Monte Carlo simulation as a tool to show the influence of the human factor into the quantitative risk assessment

•Monte Carlo simulation was used to introduce human factor into frequency calculation.•The model includes organizational, job and personal characteristics factors.•The model was applied in two real chemical plants as case studies.•The final risk assessment was more conservative and realistic. The fr...

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Bibliographic Details
Published inProcess safety and environmental protection Vol. 102; pp. 441 - 449
Main Authors González Dan, J.R., Guix, A., Martí, V., Arnaldos, Josep, Darbra, R.M.
Format Journal Article Publication
LanguageEnglish
Published Elsevier B.V 01.07.2016
Subjects
Accidents
Avaluació del risc
Chemical industry
Enginyeria química
Human factor
Indústria química
Monte Carlo method
Monte Carlo simulation
Risk assessment
Safety
Seguretat
Uncertainty
Àrees temàtiques de la UPC
Chemical industry
Uncertainty
Risk assessment
Safety
Human factor
Monte Carlo simulation
Accidents
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Summary:•Monte Carlo simulation was used to introduce human factor into frequency calculation.•The model includes organizational, job and personal characteristics factors.•The model was applied in two real chemical plants as case studies.•The final risk assessment was more conservative and realistic. The frequency of occurrence of an accident is a key aspect in the risk assessment field. Variables such as the human factor (HF), which is a major cause of undesired events in process industries, are usually not considered explicitly, mainly due to the uncertainty generated due to the lack of knowledge and the complexity associated to it. In this work, failure frequencies are modified through Monte Carlo (MC) simulation including the uncertainty generated by HF. MC is one of the most commonly approach used for uncertainty assessment based on probability distribution functions that represent all the variables included in the model. This technique has been also proved to be very useful in the risk assessment field. The model takes into account the uncertainty and variability generated by several HF variables. In order to test the model, it has been applied to two real case studies, obtaining new frequency values for the different scenarios. Together with the consequences assessment, new isorisk curves were plotted. Since the uncertainty generated by the HF has now been taken in to account through MC simulation, these new values are more realistic and accurate. As a result, an improvement of the final risk assessment is achieved.
ISSN:0957-5820
1744-3598
DOI:10.1016/j.psep.2016.04.024